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Seismic Isolation Strategies for Earthquake-Resistant Construction Seismic Isolation Strategies for Earthquake-Resistant Construction Seismic Isolation Strategies for Earthquake-Resistant Construction: Emerging Opportunities By Mikayel Melkumyan Seismic Isolation Strategies for Earthquake-Resistant Construction: Emerging Opportunities By Mikayel Melkumyan This book first published 2019 Cambridge Scholars Publishing Lady Stephenson Library, Newcastle upon Tyne, NE6 2PA, UK British Library Cataloguing in Publication Data A catalogue record for this book is available from the British Library Copyright © 2019 by Mikayel Melkumyan All rights for this book reserved. No part of this book may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, without the prior permission of the copyright owner. ISBN (10): 1-5275-1802-7 ISBN (13): 978-1-5275-1802-5 TABLE OF CONTENTS Chapter One ................................................................................................. 1 Introduction Chapter Two ................................................................................................ 9 Concepts of Dampers for the Earthquake Protection of Existing Buildings and for Displacement Restraints in Seismically Isolated Buildings 2.1. Study of the Efficiency of Tuned Single and Double Mass Dampers on a Model of a Frame Building under Vibration Tests ................... 9 2.2. Theoretical Background: Linear and Non-Linear Analyses of a Building with and without a TMD ........................................... 20 2.3. Justification of the Transition from the Concept of Flexible Upper Floor to the Concept of Isolated Upper Floor Acting as a TMD ... 31 2.4. Structural Concept of the Series 111 Nine-Storey R/C Frame Apartment Building and the Formation of its Dynamic Design Model ............................................................................................. 34 2.5. Structural Concept of an AIUF and the Non-Linear Seismic Response Analysis of a Building Protected by an AIUF ................ 43 2.6. Technical Condition of a Partly Damaged Building Selected for Testing and its Dynamic Characteristics before starting the Reconstruction Activities .......................................................... 50 2.7. Technique of Dynamic Tests and their application on a 9-Storey Full-Scale Existing Building Before and After the Erection of an AIUF ............................................................................................... 53 2.8. Analysis of the Dynamic Test Results ............................................ 61 2.9. New Structural Concept and the Application of a Roof Isolation System in the Form of an Isolated Upper Slab for the Seismic Protection of an Existing 12-Storey Office Building ...................... 63 2.10. Results of the Analysis of a 12-Storey Building Protected by a IUS Based on the Provisions of the Armenian Seismic Code and the Time Histories .......................................................... 67 2.11. New Concept of a Dynamic Damper to Restrict the Displacements of Seismically Isolated Buildings ........................... 74 2.12. Earthquake Response Analysis of a 4-Storey Seismically Isolated Building with and without DD .......................................... 76 vi Table of Contents 2.13. The First Application of DD in the Design and Construction of a Seismically Isolated Residential House ................................... 79 2.14. Non-Linear Earthquake Response Analysis of a Residential House with and without DD ........................................................... 88 Chapter Three ............................................................................................ 96 Innovative Base Isolation Strategies for the Seismic Retrofitting of Existing Frame and Stone Buildings 3.1. New Structural Concept for an Existing 4-Storey R/C Industrial Frame Building to be Retrofitted by Base Isolation and Simultaneously Reconstructed into a 6-Storey Hotel Building ....... 96 3.2. Design of Base Isolated Buildings Using an Innovative Approach to the Installation of Seismic Isolators by Clusters ...................... 111 3.3. Analysis of the Seismic Isolated Retrofitted 6-Storey Hotel Building on the Basis of the Armenian Building Code and Acceleration Time Histories ......................................................... 118 3.4. Another Base Isolation Retrofitting Strategy for an Existing R/C 8-Storey Hematology Center Hospital Frame Building with Shear Walls ............................................................................................ 122 3.5. Analysis of the Seismic Isolated Retrofitted HCHB on the Basis of the Armenian Building Code and Acceleration Time Histories .. 143 3.6. Some Characteristic Peculiarities of Base Isolation Retrofitting Design and Implementation for Existing Stone Buildings with Load-Bearing Walls ..................................................................... 147 3.7. Methodology for the Testing of Seismic Isolation Rubber Bearings, Testing Facilities and Execution of Tests ..................... 158 3.8. Base Isolation Retrofitting Design of an Existing 4-Storey Stone College Building ........................................................................... 174 3.9. Analysis of a Seismic Isolated Retrofitted 4-Storey Stone College Building on the Basis of the Armenian Building Code and Acceleration Time Histories ......................................... 187 3.10. First Attempt at Retrofitting Design for a 4-Storey Existing Damaged Stone School Building by Combination of Base Isolation with Reinforced Concrete Jackets ................................................ 190 3.11. Analysis of a Seismic Isolated Retrofitted 4-Storey Stone Damaged Building of School №68 on the Basis of the Armenian Building Code and Acceleration Time Histories .......................... 209 3.12. Some Provisions of the Armenian Building Code Regarding Seismic Isolation of Buildings and Structures .............................. 213 Seismic Isolation Strategies for Earthquake-Resistant Construction vii Chapter Four ............................................................................................ 224 Comparative Analysis of Innovative Base Isolation Retrofitting vs. Conventional Retrofitting of Existing Stone Buildings 4.1. Comparison of Retrofitting Technologies in Armenia ................ 224 4.2. Comparison of Retrofitting Technologies in Romania ................ 227 Chapter Five ............................................................................................ 232 Demonstration of the Cost-Effectiveness of Base Isolation Strategy on the Example of the 16-Storey Reinforced Concrete Frame Buildings with Shear Walls 5.1. Structural Concepts of a 16-Storey Fixed Base and Base Isolated R/C Frame Buildings with Shear Walls .......................... 232 5.2. Comparative Analysis of the Expenditure on Construction Materials in Fixed Base and Base Isolated Buildings .................. 244 Chapter Six .............................................................................................. 250 Worldwide Recognition of the Innovative Seismic Isolation Strategies Developed in Armenia About the Author ..................................................................................... 255 CHAPTER ONE INTRODUCTION The protection of existing buildings from earthquake damage is becoming more and more important with every recent seismic event across the world. In this regard, the seismic isolation of structures is becoming an increas- ingly common method of providing such protection. Particularly, roof iso- lation techniques forming different types of dampers for earthquake protection, and base isolation technologies for seismic retrofitting, devel- oped by the author of this book, have received a wide application in Ar- menia. Also, the developed base isolation technology has been implemented in Russia, and a retrofitting design has also been produced for implementation in Romania and approved by the Romanian govern- ment. It is worth noting that the above-mentioned seismic (roof and base) isolation strategies have great potential for the rehabilitation of existing civil structures such as apartment blocks and critical facilities such as schools and hospitals. In the case of base isolation, the first dynamic mode of the isolated building involves deformation in the isolation system only; the building above being to all intents and purposes rigid. The higher modes do not participate in the motion, so that the high energy in the ground motion at these higher frequencies cannot be transmitted into the building (Naeim & Kelly, 1999). By reducing the seismic forces transmit- ted, isolation protects the contents and secondary structural features, as well as the main structure. Starting in 1995, the author of this book has designed 53 buildings and structures which apply base or roof isolation systems. Of these designed buildings, the total number of already constructed and retrofitted buildings has reached 45 (Figure 1). Among them there are bath-houses, private res- idences, school buildings, clinics and hospital buildings, business centers, hotels, and apartment buildings. 2 Chapter One Figure 1. Number of seismic (base and roof) isolated buildings newly constructed or retrofitted in Armenia by years The number of seismically isolated buildings per capita in Armenia is among the highest in the world. Alongside this, seismic isolation laminat- ed rubber-steel bearings (SILRSBs) differing by shape and
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